WO1990001445A1

WO1990001445A1 - Mine-sweeping means for removing anchor cable mines

Info

Publication number: WO1990001445A1
Application number: PCT/EP1989/000803
Authority: WO
Inventors: Günter Backstein; Annette Brinkmann; Steffen Weber; Klaus-Jürgen POHL; Eckhard Knabel; Hermann Schaper
Original assignee: Rheinmetall Gmbh
Priority date: 1988-08-05
Filing date: 1989-07-11
Publication date: 1990-02-22
Also published as: EP0389576B1; US4970957A; EP0389576A1; DE3826653C1; DE58902971D1

Abstract

The high weight of mine-sweeping means transported by droning impedes the manoeuverability of the drone. To improve the manoeuverability, the invention proposes that the weight of the mine-sweeping means (100) be chosen so that it is practically unaffected by buoyancy during transport and that, after the anchor cable is encircled by the clamping device, the mine-sweeping means (100) is made buoyant by casting off a tare weight (118).

Description

Mine clearing device for clearing anchor mines

The invention relates to a mine clearing device for clearing anchor tauminen, as defined in the preamble of claim 1. Such mine clearance devices are known per se, for example from DE 35 28 329. However, the known mine clearance devices have the disadvantage that relatively complex clamping devices are required, and that the delivery drone is loaded with strong static and dynamic moments during the search run due to the heavy weight of the mine clearance device and thus disturb the drone's maneuverability. A further disadvantage of the known mine clearing device is that buoyancy means which can be activated must be used to ascend the device along the anchor rope. These require a relatively large space and are expensive and easily prone to failure.

The object of the present invention is therefore to develop a mine clearing device which can be brought in particular by underwater drones so that the

Maneuverability of the drone is influenced as little as possible by the mine clearing device and that activatable buoyancy means are not required. This object is achieved by the features of the characterizing part of claim 1.

Further particularly advantageous embodiments of the invention emerge from the subclaims.

The present invention is therefore based on the idea that the maneuverability of the combustion device, in particular the drone, is hardly disturbed by the weight of the mine space device by the mine clearance device being buoyancy-neutral during the movement process. By

The required buoyancy is then achieved by dropping a buoyancy weight so that buoyancy means that can be activated can be dispensed with.

Further advantages and details of the invention will be explained in the following with reference to an exemplary embodiment with the aid of figures. It shows:

Fig. 1 is a schematic representation for explanation

the invention; and

Fig. 2 an inventive mine clearing device.

Fig. 1 shows a schematic representation for explaining the invention. 1 denotes an anchor mine, which is connected via an anchor rope 2 (or an anchor chain) to a weight (anchor chair) 4 standing on the seabed 3. An underwater drone 5 that has a

Cable 6 is connected to the mine hunting boat, not shown, is controlled in the vicinity of the anchor rope 2. The drone 5 is connected to the mine clearing device 100 according to the invention via a delivery rod 7.

When the drone 5 approaches the anchor rope 2, the latter is pressed by the inlet rails 101, 102 into a clamping device (not shown in FIG. 1). As soon as the anchor rope 2 is in the clamping device of the mine-clearing device 100, the drone 5 with the delivery rod 7 releases from the mine-clearing device 100 and the mine-clearing device 100 according to the invention rises along the anchor line 2 to the mine 1 without activatable buoyancy means.

Fig. 2 shows the mine clearing device according to the invention in detail; The infeed rails are again designated 101 and 102. These inlet rails are located on the lead housing 103, the head part of which is identified by 104 and the lower part by 105. The clamping device consists essentially of the clamping levers 107 and 108 arranged on the head part of the housing 104 and from the lower part of the

Housing arranged and only partially visible

Clamping levers 109 and 110. The clamping levers can each be moved about pivot points 111, 112 (these pivot points are not visible for the clamping levers arranged on the lower part of the housing 105). Between the clamping levers 107 and 108 or 109 and 110 there are clamping lever guides 113. The respective clamping lever guide 113 has a pin 114, 115 which engage in guide slots 116, 117 in the respective clamping lever 114, 115. On the side of the clamping levers 107, 108 facing away from the inlet rails 101, 102, the latter engage in grooves of the buoyancy weight 118 and block this buoyancy weight.

In addition, a locking pin 126 engages in a longitudinal groove 127 of the buoyancy weight 118 and ensures a weight release of the clamping levers 107 to 110. The shipper st from 7 (FIG. 1) is at its end facing the mine clearing device 100 via an adapter 119 Taring weight 118 and the clamping levers 107 to 110 connected to the mine clearing device 100. Are there

Adapter 119 and delivery rod 7 fastened to one another by means of a pin 128.

In the housing 103 of the mine clearing device 100 there are also the detonator 122, known per se, with the cutting charge 125, which is also known from the aforementioned disclosure document DE 35 28 329, and the active charge 124.

The mode of operation of the exemplary embodiment is briefly discussed below: After a sonar pre-reconnaissance, the underwater drone 5 (FIG. 1) is brought to the anchor rope or anchor chain and attached with the mine clearing device 100. The anchor rope 2 presses against the clamping lever guide 113 and, due to the obliquely outwardly directed guide slots 116, 117, causes the clamping lever 107, 108 to clasp the anchor rope.

The ends of the clamping lever facing away from the infeed rail, which engage in grooves of the buoyancy weight 118 during the connection process, move outwards, so that the buoyancy weight is released and, if necessary, is still held by the pin 126. If the drone 5 now travels backwards, it pulls the adapter 119 and the buoyancy weight 118 back in addition to the delivery rod 7. As soon as the safety pin 126 connected to the mine clearing device 100 no longer engages in the longitudinal groove 127 of the buoyancy weight 118, the latter slips through a sleeve 129 of the adapter and falls onto the seabed.

After the mine clearing device 100 has been released from the delivery rod 7, the buoyancy caused by the loss of the buoyancy weight 118 ensures that the mine clearing device 100 ascends along the anchor rope 2 to the mine 1, the aim being that the mine clearing device approaches the mine vessel as far as possible. in order to achieve the best possible effect of the active charge 124 installed in the mine clearing device 100.

During the release process of the clearing device 100 from the delivery rod 7, electronics 121 located in the room device are activated, which, after a dead time phase, which serves to remove the delivery drone 5 from the clearing location, enables the two active charges 124, 125 in the mine clearing device 100 by means of acoustically coded sonar signals during a to ignite after a certain period of time after the clinging process.

The viral charge 124 installed in the mine clearing device 100 acts in the direction of the mine vessel and is intended to destroy it. If this does not succeed because the distance between clearing device 100 and mine vessel 1 is too large, the anchor rope 2 of mine 1 is severed by a second built-in tendon id charge 125, so that the mine can float, where it is then bombarded on the surface

is cleared. Preferably, before the ignition of the active charge 124 and the cutting charge 125, a target area illumination device, not shown here, is released by the clearing device 100, which floats to the surface and illuminates the target area, so that mines not destroyed by the active charge 124 are also cleared at night after floating can.

Reference list

1 mine, acre mine

2 anchor rope, anchor chain

3 seabed

4 weight, anchor chair

5 underwater drones

6 cables

7 delivery rod

100 mine clearing device

101 infeed rails

102 infeed rails

03 housing

104 head part of the casing

105 lower part of the housing

Clamping device, consisting of 107 clamping levers

108 clamping lever

109 clamping lever

110 clamping lever 111 pivot point

112 fulcrum

113 Clamp lever guide.

114 Pin of the clamping lever guide 115 Pin of the clamping lever guide 116 guide slots

117 guide slots

118 buoyancy weight

119 adapters

120 hydrophones

121 electronics

122 detonators

123 About broadcast cargo

124 active charge

125 cutting charge

126 locking pin

127 longitudinal groove of the buoyancy weight

128 pens

129 Sleeve of the adapter 119 for the buoyancy weight 118

Claims

P attersprehe

1. mine clearing device (100) for clearing anchor tauminen (1), the mine clearing device (100) with the housing (103) connected inlet rails (101, 102) for guiding the anchor rope (2) and a clamping device for clasping the anchor rope (2 ), and wherein the mine clearing device (100) rises after clasping the anchor rope (2) along the anchor rope (2) to the mine (1), characterized in that the weight of the mine clearance device (100) is selected such that it is in the water during the movement process is essentially buoyancy-neutral, and that - after the anchor device (2) is clutched by the clamping device - buoyancy of the mine clearing device (100) is achieved by dropping a buoyancy weight (118).

2. Mine clearing device according to claim .1, dadurchg ek indicates that the housing (103) and / or the most important assemblies (122, 124, 121) of the mine clearing device (100) made of light metal or lightweight materials, such as. B. ear foam.

3. Mine clearing device according to claim 1 or 2, characterized in that the clamping device consists of at least two clamping levers (107, 108; 109, 110), that the clamping levers (107, 108; 109, 110) each about a pivot point (111, 112) are rotatably mounted so that the parts of the clamping levers (107, 108; 109, 110) facing the inlet rails (101, 102) are connected via a clamping lever guide (113) such that when the anchor lever (2) is pressed against the clamping lever guide (113) the clamping levers (107, 108; 109, 110) enclose the anchor rope (2), and that the ends of the clamping levers (107, 108; 109, 110) facing away from the inlet rails (101, 102). that hold the buoyancy weight (118), move away from each other and thus the

Release the tare weight (118).

4. mine clearing device according to one of claims 1 to 3,

d a d u r c h g e k e n n z e i c h n e t that the tare weight (118) in addition to. the clamping levers (107, 108; 109, 110) are held by a further holding device (126) which only releases the buoyancy weight (118) when the device (5, 7) with which the mine clearing device (100) is moved, detaches from the mine clearing device (100).

5. mine clearing device according to claim 3, d a d u r c h

characterized in that the clamping device consists of four clamping levers (107, 108; 109, 110), two clamping levers each being arranged on the head part of the housing (104) and on the lower part of the housing (105). Mine clearing device according to one of Claims 1 to 5, characterized in that an underwater drone (5), which is connected to the mine clearing device (100) via a transfer rod (7), serves as the device (5, 7) for moving the mine clearing device (100) .

7. mine clearing device according to claim 1, d a d u r c h

characterized in that the coupling between the feeder rod (7) and the mine clearing device (100) takes place via an adapter (119) and the buoyancy weight (118) which is movably arranged in the adapter (119) in a sleeve (129), the adapter (119) with the delivery rod (7) is firmly connected.